Martha L. Rebbert

A new secreted protein that binds to Wnt proteins and inhibits their activites

The Wnt proteins constitute a large family of extracellular signalling molecules that are found throughout the animal kingdom and are important for a wide variety of normal and pathological developmental processes,. Here we describe Wnt-inhibitory factor-1 (WIF-1), a secreted protein that binds to Wnt proteins and inhibits their activities. WIF-1 is present in fish, amphibia and mammals, and is expressed during Xenopus and zebrafish development in a complex pattern that includes paraxial presomitic mesoderm, notochord, branchial arches and neural crest derivatives. We use Xenopus embryos to show that WIF-1 overexpression affects somitogenesis (the generation of trunk mesoderm segments), in agreement with its normal expression in paraxial mesoderm. In vitro, WIF-1 binds to Drosophila Wingless and Xenopus Wnt8 produced by Drosophila S2 cells. Together with earlier results obtained with the secreted Frizzled-related proteins,, our results indicate that Wnt proteins interact with structurally diverse extracellular inhibitors, presumably to fine-tune the spatial and temporal patterns of Wnt activity.

Accumulation and decay of DG42 gene products follow a gradient pattern during Xenopus embryogenesis

The DG42 gene is expressed during a short window during embryogenesis of Xenopus laevis. The mRNA for this gene can be first detected just after midblastula, peaks at late gastrula, and decays by the end of neurulation. The sequence of the DG42 cDNA and genomic DNA predicts a 70,000-Da protein that is not related to any other known protein. Antibodies prepared against portions of the DG42 open reading frame that had been expressed in bacteria detected a 70,000-Da protein in the embryo with a temporal course of appearance and decay that follows that of the RNA by several hours. Localization of the mRNA in dissected embryos and immunohistochemical detection of the protein showed that DG42 expression moves as a wave or gradient through the embryo. The RNA is first detected in the animal region of the blastula, and by early gastrula is found everywhere except in the outer layer of the dorsal blastopore lip. By midgastrula DG42 protein is present in the inner ectodermal layer and the endoderm; it disappears from dorsal ectoderm as the neural plate is induced and later decays in a dorsoventral direction. The last remnants of DG42 protein are seen in ventral regions of the gut at the tailbud stage.

Mesoderm Induction in Xenopus laevis Distinguishes Between the Various TGF-β Isoforms

Induction of mesoderm in ectodermal explants of Xenopus laevis blastula embryos had previously been shown to respond selectively to TGF-beta 2, with TGF-beta s 1 and 5 having no activity in this assay. As TGF-beta s 1, 2, and 3 are frequently coexpressed in tissues, we wished to examine the activity of TGF-beta 3 relative to that of TGF-beta s 1 and 2 in this assay as well as in other in vitro assays. We report here that when the activity of recombinant TGF-beta 3 is normalized to that of TGF-beta 1 in the assay for growth inhibition in CCL-64 cells, it is also equal to that of TGF-beta 1 in assays for stimulation of both anchorage-independent growth of rat NRK cells and chemotaxis of human monocytes. In contrast, in the assay for mesoderm induction, recombinant TGF-beta 3 is 10-fold more active than TGF-beta 2, inducing expression of muscle specific alpha-actin at concentrations as low as 1 ng/ml. These results suggest that more complex systems, in contrast to individual cell types, may respond selectively to the various TGF-beta isoforms and that there might be biological consequences of TGF-beta isoform switching in vivo.

Regulation of the Lim-1 Gene Is Mediated Through Conserved FAST-1/FoxH1 Sites in the First Intron

The Lim‐1 gene encodes a LIM‐homeodomain transcription factor that is highly conserved among vertebrates and is required for successful gastrulation and head formation. The expression of this gene in the mesoderm of the gastrula is known to require an activin/nodal signal. Earlier studies have shown that the Xenopus Lim‐1 (Xlim‐1) gene contains an activin response element (ARE) in its first intron, which cooperates with an activin‐unresponsive upstream promoter in the regulation of the gene. Here, we show that the Xlim‐1 ARE contains a cluster of FAST‐1/FoxH1 and Smad4 recognition sites; such sites have been shown to mediate activin/nodal responses in other genes. By using reporter constructs with mutated FAST‐1/FoxH1 sites and FAST‐1/FoxH1 protein chimeras, we show that the regulation of Xlim‐1 by activin depends on FAST‐1/FoxH1 function. Comparative studies on the zebrafish lim1 gene indicate the presence of FoxH1 sites in the first intron of this gene and provide evidence for the requirement for FoxH1 function in its regulation. These results illuminate the conserved nature of the transcriptional regulation of the Lim‐1 gene in different vertebrate animals.

Isolation and Characterization of TGF-β2 and TGF-β5 from Medium Conditioned by Xenopus XTC Cells

AbstractTGF-β2 and -β5 have been purified from medium conditioned by Xenopus cultured cells (XTC) and identified based on their N-terminal amino acid sequence analysis and biological activity. When applied in high concentrations, Xenopus TGF-β2, like porcine TGF-β2, induces expression of mesodermal markers from cultured Xenopus ectodermal explants, whereas TGF-β5 is inactive in this assay. However, the TGF-βs could be separated from the major mesoderm-inducing activity present in XTC medium. Xenopus TGF-β2 and -β5 are approximately equivalent to TGF-β1 in their abilities to inhibit the growth of mink lung CCL-64 cells, induce anchorage-independent growth of rat NRK cells, inhibit the proliferation and antibody secretion of human B-lymphocytes, and stimulate chemotaxis of human monocytes. These data establish the functional activity of TGF-β5 and suggest that more complex multicellular systems, in contrast to most isolated cells, discriminate between the different TGF-βs.

Brd4 associates with mitotic chromosomes throughout early zebrafish embryogenesis

Brd4 is a member of the BET (bromodomains and extraterminal) subfamily of bromodomain proteins that includes chromatin‐modifying proteins and transcriptional regulators. Brd4 has a role in cell cycle progression, making it indispensable in mouse embryos and cultured cells. The N‐terminal domain of Brd4 participates in a fusion oncogene. Brd4 associates with acetylated histones in chromatin, and this association persists during mitosis implicating Brd4 in epigenetic memory. Brd4 sequence, particularly the bromodomains and ET domain, is conserved in the zebrafish and Xenopus laevis proteins reported here. Brd4 is expressed and localized on mitotic chromosomes in early zebrafish embryos before and after the midblastula transition (MBT), indicating that the Brd4‐chromosome association is a conserved property that is maintained even before zygotic transcription. The association of Brd4 with acetylated histones may also be conserved in early embryos as we found that histones H3 and H4 are already acetylated during pre‐MBT stages. Developmental Dynamics 237:1636–1644, 2008. Published 2008 Wiley‐Liss, Inc.

Coordinated activation of the secretory pathway during notochord formation in the Xenopus embryo

We compared the transcriptome in the developing notochord of Xenopus laevis embryos with that of other embryonic regions. A coordinated and intense activation of a large set of secretory pathway genes was observed in the notochord, but not in notochord precursors in the axial mesoderm at early gastrula stage. The genes encoding Xbp1 and Creb3l2 were also activated in the notochord. These two transcription factors are implicated in the activation of secretory pathway genes during the unfolded protein response, where cells react to the stress of a build-up of unfolded proteins in their endoplasmic reticulum. Xbp1 and Creb3l2 are differentially expressed but not differentially activated in the notochord. Reduction of expression of Xbp1 or Creb3l2 by injection of antisense morpholinos led to strong deficits in notochord but not somitic muscle development. In addition, the expression of some, but not all, genes encoding secretory proteins was inhibited by injection of xbp1 morpholinos. Furthermore, expression of activated forms of Xbp1 or Creb3l2 in animal explants could activate a similar subset of secretory pathway genes. We conclude that coordinated activation of a battery of secretory pathway genes mediated by Xbp1 and Creb/ATF factors is a characteristic and necessary feature of notochord formation.

Gene expression in amphibian embryogenesis

The study of molecular events during the embryogenesis of Xenopus laevis has advanced as a result of the availability of molecular markers, i.e., nucleic acid and antibody probes for genes that are expressed in a temporally and spatially regulated fashion during development. In this article we summarize results on the localized expression of keratin genes and on the reconstruction of regulated transcription of the gastrula/neurula-specific DG42 gene. Furthermore, we discuss experiments that investigate molecular events during mesoderm induction and provide information on the nature of the inducing principle.

Cell Adhesion in Zebrafish Embryos Is Modulated by March8

March8 is a member of a family of transmembrane E3 ubiquitin ligases that have been studied mostly for their role in the immune system. We find that March8 is expressed in the zebrafish egg and early embryo, suggesting a role in development. Both knock-down and overexpression of March8 leads to abnormal development. The phenotype of zebrafish embryos and Xenopus animal explants overexpressing March8 implicates impairment of cell adhesion as a cause of the effect. In zebrafish embryos and in cultured cells, overexpression of March8 leads to a reduction in the surface levels of E-cadherin, a major cell-cell adhesion molecule. Experiments in cell culture further show that E-cadherin can be ubiquitinated by March8. On the basis of these observations we suggest that March8 functions in the embryo to modulate the strength of cell adhesion by regulating the localization of E-cadherin.

Habenular commissure formation in zebrafish is regulated by the pineal gland-specific gene unc119c.

Background: The zebrafish pineal gland (epiphysis) is a site of melatonin production, contains photoreceptor cells, and functions as a circadian clock pacemaker. Since it is located on the surface of the forebrain, it is accessible for manipulation and, therefore, is a useful model system to analyze pineal gland function and development. We previously analyzed the pineal transcriptome during development and showed that many genes exhibit a highly dynamic expression pattern in the pineal gland. Results: Among genes preferentially expressed in the zebrafish pineal gland, we identified a tissue‐specific form of the unc119 gene family, unc119c, which is highly preferentially expressed in the pineal gland during day and night at all stages examined from embryo to adult. When expression of unc119c was inhibited, the formation of the habenular commissure (HC) was specifically compromised. The Unc119c interacting factors Arl3l1 and Arl3l2 as well as Wnt4a also proved indispensible for HC formation. Conclusions: We suggest that Unc119c, together with Arl3l1/2, plays an important role in modulating Wnt4a production and secretion during HC formation in the forebrain of the zebrafish embryo. Developmental Dynamics 242:1033–1042, 2013.